EP0128299A1 - Arrangement for introducing additional gas streams to the intake manifold of a fuel-air mixture compression internal-combustion engine - Google Patents

Abstract

The device is intended to introduce additional gas flows (air, exhaust gas, cracked gas) in the intake channel (39) of an internal combustion engine (11) wherein the mixture is compressed by means of slots (9, 10) facing each other in the wall of the intake channel downstream of the throttle valve (2) and extended in the peripheral direction of the intake channel (39) on a peripheral angle smaller than 180<o>, to which the additional gas is supplied by one of a plurality of inlet conduits (6, 7, 8, 14, 15, 19, 20); regulation member (5) is provided to regulate the additional gas flow supplied by those inlet conduits as a function of the vacuum prevailing in the intake channel (39). The slots (9, 10) are orientated so that none of them is traversed by a partition surface separating the intake channel (39) and formed by the displacement of the longitudinal axis of the throttle shaft (21) in parallel to the very surface along the longitudinal medial line of the intake channel (39). Such a device provides for a good preparation of the mixture and consequently an enhancement of the thermal efficiency of the internal combustion engine while enabling to lower the fuel consumption and the noxious gas content in the exhaust gas.

Description

The invention relates to a device with the features specified in the preamble of claim 1. Such a device is known from DE-PS 24 02 970 as an additional device for mixture-compressing internal combustion engines with carburettors. The known device is used to lift the fuel, which is deposited as condensate in the intake duct downstream of the throttle valve on the intake duct wall, from the wall of the intake duct, to atomize it and to achieve a thorough mixing of the fuel-air mixture. For this reason, two opposing slots are arranged downstream of the throttle valve in the wall of the intake duct, through which additional air flows into the intake duct. The slots are so dimensioned and the amount of additional air that is fed to the slots is controlled by a special, second throttle valve, the position of which depends on the position of the throttle valve of the carburetor, so that the additional air flows into the slots in the transition area from idling to Partial load operation of the internal combustion engine at very high speed, and in partial load operation of the internal combustion engine even escapes approximately at the speed of sound.

This can be achieved by providing the cross-section of the feed lines which lead the additional air to the slots with a cross-section which is larger than the common opening cross-section of the slots, so that the slots have a certain degree of opening act on the second throttle valve as a measuring cross-section, ie form the only limit for the throughput of the additional air from then on.

The known device ensures that the second throttle valve, which controls the amount of additional air, opens even at low speeds, so that the throughput of the additional air through the slots increases steadily from low speeds to a predetermined speed in the medium speed range. From this average speed, the air throughput through the slots remains practically constant. As a result, good efficiency and a low proportion of nitrogen oxides in the exhaust gas are achieved over practically the entire speed range of an internal combustion engine equipped with such a device. This is because a relatively lean mixture is burned practically over the entire speed range. The excess air in this mixture, which can be of the order of about 20%, reduces the nitrogen oxide content in the exhaust gas, while at the same time the internal combustion engine can work with wear-friendly, relatively low temperatures.

Working with excess air is made possible by the fact that the additional air flowing out of the slots at high speed detaches and atomizes the fuel condensed there from the intake duct wall and that Homogenized fuel-air mixture. Furthermore, the known device has a favorable influence on fuel consumption because, because of working with excess air, the fuel used can be burned more completely than without such a device.

The above statements regarding the device known from DE-PS 24 02 970 apply in the same way to the device according to the invention. This is expressly pointed out to avoid repetitions.

The invention has for its object to further develop a device of the type mentioned in such a way that the efficiency of an internal combustion engine equipped therewith is further improved and the proportion of toxic components in the exhaust gas, in particular nitrogen oxides, is further reduced.

This object is achieved by a device with the features specified in claim 1. Advantageous developments of the invention are the subject of the dependent claims.

The number of slots should be at least two; in this case, one of the slots is on one side and the other slot on the other side of the imaginary parting area of the exhaust duct. However, there can be several on each side of the division area Slots may be provided. The slots can all be supplied with the same gas, for example with additional air or with exhaust gas or with another gas mixture. However, it is entirely possible to supply different slots with different gas flows, for example one slot with exhaust gas and another slot with additional air.

The invention makes use of the observation that near the throttle valve in the intake duct of the internal combustion engine, the fuel - insofar as it is an internal combustion engine with a carburetor - is predominantly deposited in the peripheral region of the intake duct on the intake duct wall where the opening width of the gap between the throttle valve and the intake duct wall is largest, i.e. in the middle between the ends of the throttle valve shaft. Since the gap between the throttle valve and the intake duct wall near the ends of the throttle valve shaft is relatively narrow in the lower and middle part-load operation of the internal combustion engine, only a relatively small amount of the fuel-air mixture can pass through there and therefore only a relatively small amount of the fuel in condense the corresponding peripheral area of the intake duct wall in the vicinity of the throttle valve. Slots for additional air, which are arranged in the same circumferential area as the ends of the throttle valve shaft, therefore contribute to the atomization of the fuel and to the homogenization of the fuel-air. Mixtures not much. It is therefore provided according to the invention to orient the slots so that they lie in those two circumferential areas of the intake duct wall where the opening width of the crescent-shaped slots between the throttle valve and the intake duct wall is greatest and most fuel is deposited on the intake duct wall. With this orientation, the slots can be most effective.

In the prior art, no consideration has been given to the orientation of the slots in relation to the position of the throttle valve shaft in the intake duct.

The inventive orientation of the slots in the intake duct leads to a noticeably better mixture preparation, which results in more complete combustion and lower poison gas proportions in the exhaust gas.

Surprisingly, it was also found that the arrangement of such slots is not only advantageous for mixture preparation in internal combustion engines which are equipped with a carburettor, but also in internal combustion engines which work with an injection of the fuel and with a return of exhaust gases into the intake duct. So far, the exhaust gas recirculation occurs in gasoline injection engines and in diesel engines in such a way that the exhaust line and connects the intake duct of the engine to one another by a connecting line which opens laterally into the wall of the intake duct, namely downstream of the throttle valve, if one is provided. So far, however, no particular attention has been paid to mixing the recirculated exhaust gases in the intake duct as homogeneously as possible with the fresh combustion air. It has been shown, however, that even in this case of exhaust gas recirculation in internal combustion engines that work with fuel injection, homogeneous mixing of the recirculated exhaust gases with the combustion air in the intake duct downstream of the point at which the fuel injection takes place has a very favorable effect on the combustion process and also leads to more complete combustion and lower levels of poison gas in the exhaust gas. In a further development of the invention, it is therefore proposed to provide slots for the exhaust gas recirculation in the intake duct even in internal combustion engines that work with an injection of the fuel, which slots are arranged, if a throttle valve is present in the intake duct, as specified in claim 1. However, since in this application the exhaust gases are introduced into the intake duct at a point upstream of the fuel injector and therefore, unlike when the invention is applied to carburetor engines, the back guided exhaust gases only mix homogeneously with the combustion air and should warm it up, but do not have to detach and atomize fuel condensate from the intake duct wall near their entry point in the intake duct, the orientation of the slots is of lesser importance; However, by arranging the slots in the circumferential direction of the intake duct and ensuring high outflow velocities by means of appropriately narrow slots, it is to be ensured that the exhaust gases of the combustion air are mixed in as uniformly as possible over the entire cross section of the intake pipe. High outflow speeds are achieved if the opening cross-section is selected to be smaller than the cross-section of the feed line which leads the exhaust gases to the slots, so that from a certain speed of the internal combustion engine alone the slots limit the exhaust gas throughput, i.e. act as a measuring cross-section.

The return of exhaust gas into the intake duct of an internal combustion engine is not only useful in internal combustion engines that work with an injection of the fuel, it can also be used with particular advantage in internal combustion engines that are equipped with carburettors. In a further development of the invention, it is therefore proposed that the supply line for the gas to be fed to the slots from the exhaust gas to branch off the internal combustion engine and to arrange a heated catalyst in this feed line, e.g. based on platinum or nickel based, which by chemical-catalytic conversion of the water vapor contained in the recirculated exhaust gas stream with other reactive components of the exhaust gas, e.g. not yet completely burned hydrocarbons with the supply of energy generates hydrogen. A simple exhaust gas recirculation is therefore not proposed, but rather a recirculation of fission gas obtained catalytically from exhaust gas; the hydrogen contained in the cracked gas improves the ignitability of the air-fuel mixture leaned by the exhaust gas recirculation and thus allows the mixture to become leaner than would be possible without the catalytic treatment of the exhaust gas.

Such a catalytic treatment of the recirculated exhaust gases is useful not only in internal combustion engines that are equipped with carburettors, but also in those that work with fuel injection, especially in gasoline injection engines.

A ceramic body coated with platinum or nickel, in particular one made of an A1 ₂ 0 ₃ ceramic, is suitable as the gap catalyst. The catalyst can be heated directly by electrical current, e.g. from the car battery, take place, but also indirectly or - if a catalyst with a sufficiently low working temperature is selected - through the exhaust gas flow itself.

If too little hydrogen can be obtained by catalytic treatment of the exhaust gas alone for a significant improvement in the ignition behavior of the air-exhaust gas / fuel mixture, then the ignition behavior can be further improved by adding a fuel to the recirculated exhaust gas upstream of the catalytic converter, which is used for catalytic Obtaining hydrogen is chemically converted with the water vapor contained in the exhaust gas. It is expedient to supply the same fuel that is to be burned in the internal combustion engine anyway. However, it is also possible, albeit with greater effort, to use other fuels such as Add alcohol, natural gas or the like.

Instead of a cracking catalyst or in combination with a cracking catalyst, a thermal reactor can also be provided for the production of hydrogen from the exhaust gases and, if appropriate, auxiliary materials supplied, the inner surface of which is preferably made at least partly from catalytically active material or coated with such a material. Such a The thermal reactor cannot be heated by the exhaust gases alone, but requires additional heating, preferably by electrical means.

If the catalyst and / or the reactor is electrically heated, it is possible to control the extent of the fission gas production by means of a relatively simple control of the heating power and to adapt it quickly and optimally to the changing operating conditions of the internal combustion engine.

The recycling of cracked gas has the advantage that the fuel consumption can be reduced due to the reduced throttle losses by heating the fuel-air mixture in part-load operation and that a reliable ignition and burning through of the emaciated fuel-air mixture is achieved. As a result, the result is a reduced proportion of poison gas in the exhaust gases, while at the same time reducing fuel consumption.

When flowing through the slots, the cracked gas effects both dynamic and thermal conditioning of the fuel condensate in internal combustion engines with a carburettor, combined with homogenization of the overall mixture _. and the hydrogen it contains a safe ignition.

In internal combustion engines without a carburetor, there is of course no need to process the fuel condensate on the intake duct wall, but even there the homogenization of the exhaust-air mixture leads to improved combustion. In all cases, however, the return of cracked gas and the arrangement of the slots in the intake duct work together in the sense of a combination.

The device according to the invention is also suitable for retrofitting internal combustion engines. When used on internal combustion engines with a carburetor, a flat lower part, in particular a plate, can be attached to the carburetor underside, in which a hole is provided which forms part of the intake duct and in which the slots and part of the feed line to these are formed. The device can be quite simple and inexpensive if the slots and the feed line are worked into the top of the lower part, for example by milling, and this lower part is then attached to the underside of the carburetor, so that the bottom of the carburetor is cut by milling or the like. covers formed recesses and added to functional slots and a functional supply line.

The invention is explained in more detail below on the basis of two exemplary embodiments.

• Figur 1 eine Vorrichtung zur Aufbereitung von flüssigen Brennstoffen für gemischverdichtende Brennkraftmaschinen mit Vergaser und zwar einem Schnitt gemäß der Linie I-I in Figur 2 durch das Vergaser-Unterteil,
• Figur 2 den Längsschnitt II-II durch die in Figurl dargestellte Vorrichtung,
• Figur 3 die schematisiert gezeichnete Gewinnung von Spaltgas aus dem Abgas der Brennkraftmaschine,
• Figur 4 eine Vorrichtung zur Rückführung von Abgasen in den Ansaugkanal eines Ottomotors mit Saugrohreinspritzung des Brennstoffs, teilweise im Schnitt,
• Figur 5 den Querschnitt V-V durch die in Fig. 4 dargestellte Vorrichtung, und
• Figur 6 den Querschnitt durch das die erfindungsgemäßen Schlitze tragende Einbauteil, und zwar entlang der Schnittlinie VI-VI gemäß Figur 5.

Show it:

• 1 shows a device for the preparation of liquid fuels for mixture-compressing internal combustion engines with a carburetor, namely a section along the line II in FIG. 2 through the lower part of the carburetor,
• FIG. 2 shows the longitudinal section II-II through the device shown in FIG. 1,
• FIG. 3 shows the schematically drawn extraction of fission gas from the exhaust gas of the internal combustion engine,
• FIG. 4 shows a device for returning exhaust gases into the intake duct of a gasoline engine with intake manifold injection of the fuel, partly in section,
• 5 shows the cross section VV through the device shown in Fig. 4, and
• 6 shows the cross section through the built-in part carrying the slots according to the invention, specifically along the section line VI-VI according to FIG. 5.

In the exemplary embodiment shown in FIGS. 1 to 3, a flat additional part 3 is flanged to the underside of the carburetor 1 of the internal combustion engine 11, in which a circular passage is provided as a continuation of the intake duct 39 of the carburetor. This circular passage is surrounded by two opposing circular segment-shaped slots 9 and 10, which extend in the circumferential direction of the intake duct 39 and to which a gas, e.g. Air, exhaust gas or a cracked gas is supplied. The feed line consists of a ring channel 8 connecting both slots 9, 10, largely enclosing the intake duct, and an adjoining, flat channel 7 running in the additional part 3, which channel extends into a channel 7 running on the additional part 3, which extends into a channel on the additional part 3 attached connecting piece 4 continues, in which a throttle valve 5 is arranged. A pipe 6 and possibly further feeder sections 14, 15, 19 and 20 are connected to the connecting piece 4.

This throttle valve 5 is closed when the internal combustion engine is idling; their position depends on the negative pressure in the intake duct 39 and for this purpose the throttle valve 5 can be in mechanical connection with the throttle valve 2 of the carburetor 1 in such a way that it is opened when the throttle valve 2 is in transition from idle mode to part-load and full-load operation is opened.

One could also control the throttle valve 5 by means of a vacuum box, which responds to the vacuum in the intake duct 39. The throttle valve 2 of the carburetor is located upstream of the slots 9, 10 close to these in the intake duct 39.

The gas entering via the opened throttle valve 5 in the direction of arrow 22 is drawn in by the internal combustion engine and flows through channel 7 and ring channel 8. In the area of channel 7, the gas flow is divided, some of which in the direction of the arrow 23 flows through the slot 9 into the intake duct 39, while the other gas stream flows with a slight time delay in the direction of arrow 24 through the opposite slot 10 into the intake duct 39.

As can be seen from the illustration in FIG. 1 with regard to the arrows 23 and 24 shown, the two slits 9, 10, which are designed in the form of a segment of a circle, are arranged diametrically opposite one another, namely symmetrically to the longitudinal axis of the throttle valve shaft 21 parallel to itself by shifting the longitudinal axis of the intake duct 39, imaginary dividing surface of the intake duct 39 (which is a plane in the case of a cylindrical outlet duct). The straight line connecting the two center points 40, 41 of the slots 9 and 10 divides this imaginary dividing surface at a right angle. Downstream of the throttle valve 2 strikes those areas of the wall of the intake duct 39 where, in the part-load mode, that is, with a smaller opening up to approximately a 3/4 opening of the throttle valve 2, the greatest width of the crescent-shaped passages for the fuel-air mixture, the greatest proportion of fuel condensate is low, and it is precisely in these areas that the two slots 9, 10 are according to the invention arranged.

On both sides of the throttle valve shaft 21, when the throttle valve 2 is opened, narrow and then widening crescent-shaped openings through which the fuel-air mixture flows first form between the latter and the wall of the intake duct 39. During part-load operation, these openings are so narrow that the mixture has to squeeze through so close to the intake duct wall that the fuel contained in the mixture condenses in part on the intake duct wall.

Since the two crescent-shaped openings formed between the throttle valve 2 and the intake duct wall are very narrow near the ends of the throttle valve shaft 21 during part-load operation, very little mixture and thus fuel passes through there. A condensate treatment at the place of Ansaugkanalumfangs, for example by a circumferential Rin ^g slot, only about half of the flow of energy in the supplied auxiliary gas to the correct and necessary places would bring into effect and the treatment effect in the lower region of the partial load operation (eg in city traffic) bring a minimum.

Accordingly, the design and geometric arrangement of the slots 9, 10 in the intake duct wall according to the invention is very important depending on the orientation of the throttle valve shaft 21 and the location of the maximum condensate formation.

The slots 9 and 10 are dimensioned in their cross-section such that the throttle valve 5 opens a larger passage even at a low speed of the internal combustion engine 11 and therefore no longer acts as a cross-section limiting gas throughput in the connecting piece 4.

The tube 6, the channel 7 and the ring channel 8 have a larger passage cross section than the slots 9 and 10 and therefore the latter act as a measuring cross section (ie as the only limitation) for the gas throughput from about a driving speed of 80-100 km / h, whereby the gas emerging from slots 9 and 10 reaches speeds of 100 m / s and more.

A particularly good thermal efficiency of the internal combustion engine, a further reduction in the fuel requirement and a further reduction in the amount of poisonous gas in the exhaust gas are achieved if, instead of additional air, a cracked gas generated by catalytic treatment of part of the exhaust gases via the pipe 6 and the connecting piece 4 to the slots 9 and 10 leads. The internal combustion engine 11 shown in FIG. 3 has an exhaust manifold 12 which does not have a flange 13 in in a more detailed manner merges into the exhaust silencer. From the exhaust gases flowing in the exhaust manifold 12 in the direction of arrow 27, a part is branched off in the region of the flange 13 in the direction of arrow 28, which flows there into a channel 14, which forms the entrance to a thermal-catalytic reactor 15 on the rear on the Flange 13 is attached.

In the reactor 15, a heating wire 16 made of a catalytically active metal is attached, which is connected via electrical lines 17 and 18 with electrical energy e.g. is powered by the car battery. The energy supply and the simultaneous action of the catalyst on the recirculated exhaust gases result in a chemical catalytic reaction of the water vapor contained in the exhaust gases with the unburned hydrocarbons and carbon monoxide residues still present in the exhaust gases, as a result of which hydrogen is released.

The outlet connector 19 of the reactor 15 is connected to the tube 6 of the carburetor additional part 3 via a connecting line 20. The cracked gas flows in the connecting line 20 in the direction of the arrow 29.

The inner surface of the reactor 15 can be provided with a material which acts as a gap catalyst, such as nickel, for better catalytic action of the reactor. It is also advantageous if the reactor 15 is supplied not only with exhaust gases, but also with combustible auxiliaries such as natural gas or alcohol, but in particular gasoline; this means that a larger proportion of the water vapor contained in the exhaust gases can be converted chemically to produce hydrogen, the hydrogen having a favorable effect on the combustion process.

Instead of a thermal-catalytic reactor 15, it would also be possible to provide a gap catalytic converter, which is expediently heated electrically and which could consist of a gas-permeable body made of a ceramic (eg made of A1 ₂ 0 ₃ ) coated with catalytically active metal (eg platinum or nickel), which is housed in a chamber through which the exhaust gases flow. The auxiliary gas flowing in the direction of the arrow / into the channel 7, in particular cracked gas, has a strong condensate-lifting effect at the slots 9, 10 lying opposite one another, that is to say that the fuel condensate creeping along the wall of the intake channel 39 becomes in the direction of the arrows 25 and 26 finely nebulized and lifted off the wall of the intake duct 39. This achieves dynamic and thermal fine atomization of the fuel and homogenization of the fuel-air mixture; If a cracked gas is added as the auxiliary gas, then, because of the hydrogen content in the cracked gas, good ignition of such a lean mixture that would hardly be ignitable without the cracked gas introduced is achieved. In addition, the nitrogen oxides NO _x in the exhaust gas are drastically reduced by the return of non-combustible nitrogen from the exhaust gas into the carburetor additional part 3.

According to investigations carried out with the addition of hydrogen in part-load operation of a gasoline engine, only approx. 1 kg of hydrogen to 25 kg of gasoline are required to achieve very low proportions of CO, hydrocarbons and NOx in the exhaust gas. This amount can be obtained from about 1/4 of the water vapor content in the exhaust gas by catalytic chemical conversion.

The exhaust gas recirculation through the slots 9, 10 is preferably limited in such a way that the requirement for hydrogen in the recirculated exhaust gas corresponds to an amount which arises at a driving speed of 80-100 km / h.

As an example: a modern mid-range car requires an output of approx. 18 KW at a driving speed of 100 km / h. With the mixture preparation according to the invention, about 4 kg of gasoline per hour are used for this. The slots 9, 10 are dimensioned such that 0.04 kg of hydrogen make their way through the slots 9, 10 with the recirculated exhaust gas. At higher loads (engine output), the relative hydrogen content in the gasoline then decreases; at lower outputs, the amount of exhaust gas supplied is controlled by means of the throttle valve 5. This results in a high exit speed of the recirculated gas at the slots 9, 10 in the main driving area at partial load operation and thus a good treatment of the gas condensed on the intake duct wall and a homogeneous mixing of both gas streams in the intake duct 39. This is very important so that all cylinders of the internal combustion engine 11 received a uniformly composed fuel-air-auxiliary gas mixture.

In the second exemplary embodiment shown in FIGS. 4-6, parts which correspond to parts of the first exemplary embodiment are denoted by corresponding reference numerals.

The "internal combustion engine 11" shown in FIG. 4 is an Otto engine with intake manifold injection of the fuel.

One can see an intake pipe 39a which extends laterally from the cylinder head 50 of the engine 11 and branches off from a manifold intake pipe 39b which connects the intake pipes 39a of the various cylinders of the engine 11 to one another. On the manifold pipe 39b there is a double suction pipe 39c, to which a double air suction pipe 39d with two parallel air suction channels 39 and 39 'is flanged with the interposition of an additional part 3 for exhaust gas recirculation. Upstream of the additional part 3 there is a throttle valve 2 in each of the intake ducts 39. The additional part has two circular through openings next to one another, open diametrically opposite into one of the two intake ducts, namely into the intake duct 39. The two slots 9 and 10 are connected via a ring channel 8 and a channel 7 to a connecting piece 4 of the additional part 3; a feed line 6 leads to the inlet of the connecting piece 4 and branches off from the exhaust line 12 of the engine 11. In the connecting piece 4 there is a throttle valve 5, with which the throughput of the recirculated exhaust gas can be controlled as a function of the negative pressure in the intake duct 39.

As described with reference to the first exemplary embodiment, the exhaust gases enter the intake duct 39 at high speed through the slots 9 and 10 even at the relatively low engine speeds in the transition region between the Leorlauf operation and the part-load operation and mix very homogeneously with the intake air as a result of the high inflow speed Combustion air. In order to ensure a high inflow speed of the exhaust gases, the cross section of the through opening in the additional part 3 at the point where the slots 9 and 10 are located is narrowed compared to the cross section of the section of the intake duct in front of it, which results in the mode of operation of a Venturi nozzle. This is particularly advantageous in the case of full-load operation of the engine, when the negative pressure in the intake duct 39 is no longer as strong, and in the case of injection engines which are equipped with a turbocharger.

In the illustrated embodiment, the exhaust gases are only returned to one of the two intake channels 39 and 39 ', but it is readily possible within the scope of the invention to feed the returned exhaust gases into both intake channels 39 and 39 ¹ ; one only has to provide slots in both intake ducts from which the exhaust gases can escape.

4 and 5 that the slots 9 and 10 have the / claim 1 as the orientation claimed according to the invention relative to the position of the longitudinal axis of the throttle valve shaft 21.

The exhaust gas recirculation through the slots 9 and 10 causes a homogeneous mixing of the recirculated exhaust gases with the combustion air, and the fuel is injected into this homogeneous mixture at the end of the intake pipe 39a from the injection nozzle 51 arranged there.

In a corresponding manner, as was described in connection with the first exemplary embodiment, the recirculated exhaust gases can also be guided in the second exemplary embodiment on the way from the exhaust line 12 to the connecting piece 4 via a gap catalyst or via a thermal reactor or via a combination of both, to add a hydrogen-containing cracking gas to the combustion air instead of exhaust gas; As described above, hydrogen production can be promoted by adding a fuel to the catalyst and / or the reactor in addition to the exhaust gas.

Claims (13)

1. Device for introducing additional gas flows into the intake duct of a mixture-compressing internal combustion engine by means of slots located opposite one another in the intake duct wall downstream of the throttle valve and extending in the circumferential direction of the intake duct over a circumferential angle of less than 180 °, which the additional gas is passed through one or more supply lines is supplied, a control element, in particular a further throttle valve or a valve, being provided for controlling the throughput of the additional gas through these supply lines as a function of the negative pressure prevailing in the intake duct in each supply line,
characterized in that the dividing surface which divides the intake duct (39) and is produced by shifting the longitudinal axis of the throttle valve shaft (21) parallel to itself along the longitudinal center line of the intake duct (39) does not pass through any of the slots (9, 10). 2. Apparatus according to claim 1, characterized in that the slots (9, 10) at a predetermined dimensions of the slots (9,10) and the suction channel (39) have the greatest possible distance from the dividing surface. 3. Device according to claim 1 or 2 with two slots (9, 10) in the intake duct (39), characterized in that the connecting straight line of the two center points (40, 41) of the slots (9, 10) intersects the dividing surface at a right angle . 4. Device according to one of the preceding claims, characterized in that the internal combustion engine (11) is a diesel engine or a gasoline engine with intake manifold injection of the fuel and the supply line (6,7,8,14,15,19) leading to the intake duct (39), 20) branches off from the exhaust line (12) of the internal combustion engine (11). 5. Device for returning exhaust gases into the intake duct of a mixture-compressing internal combustion engine working with fuel injection through a feed line branching off the exhaust gas line of the internal combustion engine and leading to the intake duct, in which, if necessary, to control the throughput of the recirculated exhaust gases depending on the negative pressure prevailing in the intake duct Control member, in particular a throttle valve or a valve is provided,
characterized in that the feed line (6, 7) opens into one or more slots (9, 10) extending in the circumferential direction of the intake duct (39), which are so narrow for a given cross-section of the feed line (6, 7) that the exhaust gases flow out of them at a very high speed to the speed of sound even in the transition area between idling and part-load operation. 6. The device according to claim 5, characterized in that the slots (9,10) are arranged opposite one another. 7. The device according to claim 4, 5 or 6, characterized in that the suction channel (39) in the region of the slots (9,10) has a cross-sectional constriction in the manner of a Venturi nozzle. 8. The device according to claim 7, characterized in that the downstream of the slots (9,10) section of the intake duct (39) is designed as a diffuser. 9. Device according to one of claims 1 to 3 or 5 to 8, characterized in that the feed line (1) branches off from the exhaust line (12) of the internal combustion engine (11) and that in the feed line (6,7,8, 14,15 , 19, 20) for generating cracked gas from exhaust gas, a thermal reactor (15) and / or a heated cracking catalyst (16), for example - is arranged on a platinum basis or on a nickel basis. 10. The device according to claim 9, characterized in that a fuel is fed into the feed line upstream of the reactor (15) or the gap catalyst (16). 11. The device according to claim 9 or 10, characterized in that the inner surface of the reactor (15) consists at least partially of catalytically active material or is coated with a catalytically active material. 12. The apparatus of claim 9 or 10, characterized in that for heating the gap catalyst (16) and the recirculated exhaust gases in the line returning the exhaust gases upstream of the gap catalyst (16), a heating element, in particular a heating coil is attached. 13. The apparatus according to claim 1 for internal combustion engines (11), which are equipped with a carburetor (1), on the underside of which is designed as a carburetor, flat lower part (3) is attached, in which a hole as part of the intake duct (39) and the openings of the slots (9, 10) are formed together with part of the feed line (7, 8) leading to the slots (9, 10),
characterized in that, in order to form the slots (9, 10) and part of the feed line (7, 8), the flat lower part (3) is provided on its upper side with recesses which are open at the top and which are covered by the carburetor underside.

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